Molecular Gas Structure and Star Formation Diversity in Stephan's Quintet Revealed by ACA CO(1-0) Mapping

Abstract

We present 12CO(1-0) mapping across the entire system of Stephan's Quintet, a well-known compact galaxy group, observed by Atacama Compact Array (7\,m array + Total Power) of the Atacama Large Millimeter/submillimeter Array. These observations provide the first large-scale (137\,kpc×119\,kpc), spatially resolved (5.5\,kpc) molecular gas map of a compact group. Our CO map revealed that most of the molecular gas resides in the disk of the member galaxy NGC~7319 and in the intergalactic regions, including components along the shocked filament and the optically identified tidal tail extending from NGC~7319. Along the tidal tail and its surroundings, we found not only an extended molecular gas component but also four discrete CO clumps, with velocity dispersions of 10-30 km\,s-1 and molecular gas masses of order 107-108\,M. Three of these clumps spatially overlap with H\, i, whereas the remaining clump shows no associated H\, i or counterparts at optical and infrared wavelengths. Using star formation rates derived from Hα luminosities of H\, ii regions, we found that star formation efficiencies (SFEs) span 2.2\,dex (0.02--4\,Gyr-1) and negatively correlate with CO velocity dispersion. While regions with small velocity dispersion exhibit SFEs comparable to those of nearby disk galaxies, those with large velocity dispersion (50-150\,km\,s-1) around the shocked filament show strongly suppressed star formation. These results suggest that turbulence plays a significant role in regulating star formation in interacting systems.